Wireless electromagnetic receiver and wireless power transfer system

ABSTRACT

A system and a device for wirelessly transferring power without a cable are provided. A wireless electromagnetic receiver includes a first device configured to oscillate based on an electromagnetic field. The wireless electromagnetic receiver further includes a second device configured to transform the oscillation of the first device into a power, the second device being in contact with the first device.

CROSS-REFERENCE TO RELATED APPLICATION(S)

This application claims the benefit under 35 U.S.C. §119(a) of Russian Patent Application No. 2011137641, filed on Sep. 13, 2011, in the Russian Federal Service for Intellectual Property, and Korean Patent Application No. 10-2012-0083076, filed on Jul. 30, 2012, in the Korean Intellectual Property Office, the entire disclosures of which are incorporated herein by reference for all purposes.

BACKGROUND

1. Field

The following description relates to a system and a device for transferring power without a cable.

2. Description of Related Art

Electromagnetic wireless power transfer systems are classified into radiative systems and non-radiative systems. Radiative power transfer systems are based on narrow-beam transmitters, and utilize electromagnetic radiation in a far field. Non-radiative power transfer systems are based on electromagnetic induction, and utilize non-radiation in a near field.

Interest in non-radiative power transfer systems has grown significantly after a resonance power transfer scheme was proposed. Nearly all known resonance-based devices transferring wireless power are based on electromagnetic resonator structures. Resonator structures used for resonance power transfer systems may also be used in non-resonance systems, for example, radiative systems.

A drawback of electromagnetic resonator structures includes the complicated process of manufacturing a small-sized, sensitive electromagnetic resonator with a high quality factor (Q-factor Q). Another drawback includes complications with production of an electromagnetic resonator including a high Q-factor but a low resonance frequency. To increase an efficiency of a power transfer process, it is desirable to make a Q-factor of an electromagnetic resonator as high as possible.

SUMMARY

In one general aspect, there is provided a wireless electromagnetic receiver including a first device configured to oscillate based on an electromagnetic field. The wireless electromagnetic receiver further includes a second device configured to transform the oscillation of the first device into a power, the second device being in contact with the first device.

The first device may include an integral solid-state mechanical resonator made of a magnetostrictive material, the integral solid-state mechanical resonator configured to oscillate based on the electromagnetic field. The second device may include a transducer configured to transform the oscillation of the integral solid-state mechanical resonator into the power.

The electromagnetic field may be at a frequency corresponding to a resonance frequency of the first device.

The second device may be further configured to maintain a quality factor (Q-factor) of the first device.

The first device may be made of a magnetostrictive material with a Q-factor including a value exceeding 2000.

The first device may be made of a magnetostrictive ferrite.

The first device may include a shape so that the power includes a peak value at an operating frequency.

The first device may include a shape of a cylinder.

The first device may include a shape of a bar with a square cross-section.

The first device may include a shape of a plate.

The wireless electromagnetic receiver may further include a permanent magnet configured to bias the first device.

The permanent magnet may be made of magnetic ceramics.

The second device may include a precharged capacitor.

The second device may include two conductive layers. The second device may further include an electret layer configured between the two conductive layers.

At least one of the two conductive layers may include a metallized surface configured to cover a portion of a surface of the first device.

At least one of the two conductive layers may include a conductor mechanically connected to a surface of the first device.

At least one of the two conductive layers may be not mechanically connected to the first device.

The wireless electromagnetic receiver may further include a load connected to the two conductive layers.

In another general aspect, there is provided a wireless power transfer system including a transmitter configured to generate a magnetic field to transmit power. The wireless power transfer system further includes a wireless electromagnetic receiver configured to receive the power from the transmitter. The wireless electromagnetic receiver includes a first device configured to oscillate based on the magnetic field. The wireless electromagnetic receiver further includes a second device configured to transform the oscillation of the first device into the power, the second device being in contact with the first device.

The transmitter may include a non-radiative resonance structure with a resonance frequency f that is located at a distance less than a wavelength λ from the wireless electromagnetic receiver, where λ=c/f, and c denotes a speed of light.

The transmitter may include a non-radiative non-resonance structure located at a distance less than a wavelength λ from the wireless electromagnetic receiver, where λ=c/f, and c denotes a speed of light.

The transmitter may include a radiative structure with a frequency f that is located at a distance greater than a wavelength λ from the wireless electromagnetic receiver, where λ=c/f, and c denotes a speed of light.

Other features and aspects will be apparent from the following detailed description, the drawings, and the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a diagram illustrating an example of a wireless power transfer system.

FIG. 2 is a diagram illustrating an example of a wireless electromagnetic receiver.

FIG. 3 is a diagram illustrating another example of a wireless electromagnetic receiver.

FIG. 4 is a diagram illustrating another example of a wireless power transfer system.

Throughout the drawings and the detailed description, unless otherwise described, the same drawing reference numerals will be understood to refer to the same elements, features, and structures. The relative size and depiction of these elements may be exaggerated for clarity, illustration, and convenience.

DETAILED DESCRIPTION

The following detailed description is provided to assist the reader in gaining a comprehensive understanding of the methods, apparatuses, and/or systems described herein. Accordingly, various changes, modifications, and equivalents of the systems, apparatuses, and/or methods described herein will be suggested to those of ordinary skill in the art. The progression of processing steps and/or operations described is an example; however, the sequence of steps and/or operations is not limited to that set forth herein and may be changed as is known in the art, with the exception of steps and/or operations necessarily occurring in a certain order. Also, description of well-known functions and constructions may be omitted for increased clarity and conciseness.

FIG. 1 is a diagram illustrating an example of a wireless power transfer system. Referring to FIG. 1, the wireless power transfer system includes a source device 110 and a target device 120. The source device 110 is a device supplying wireless power, and may be any of various devices that supply power, such as pads, terminals, televisions (TVs), and any other device that supplies power. The target device 120 is a device receiving wireless power, and may be any of various devices that consume power, such as terminals, TVs, vehicles, washing machines, radios, lighting systems, and any other device that consumes power.

The source device 110 includes a variable switching mode power supply (SMPS) 111, a power amplifier 112, a matching network 113, a controller 114, a communication unit 115, a power detector 116, and a source resonator 131. The target device 120 includes a matching network 121, a rectifier 122, a direct current-to-direct current (DC/DC) converter 123, a communication unit 124, a controller 125, a power detector 127, and a target resonator 133.

The variable SMPS 111 generates a DC voltage by switching an alternating current (AC) voltage having a frequency of tens of hertz (Hz) output from a power supply. The variable SMPS 111 may output a DC voltage having a predetermined level, or may output a DC voltage having an adjustable level by the controller 114.

The power detector 116 detects an output current and an output voltage of the variable SMPS 111, and provides, to the controller 114, information on the detected current and the detected voltage. Additionally, the power detector 116 detects an input current and an input voltage of the power amplifier 112.

The power amplifier 112 generates a power by converting the DC voltage output from the variable SMPS 111 to an AC voltage using a switching pulse signal having a frequency of a few kilohertz (kHz) to tens of megahertz (MHz). In other words, the power amplifier 112 converts a DC voltage supplied to a power amplifier to an AC voltage using a reference resonance frequency F_(Ref), and generates a communication power to be used for communication, or a charging power to be used for charging that may be used in a plurality of target devices. The communication power may be, for example, a low power of 0.1 to 1 milliwatts (mW) that may be used by a target device to perform communication, and the charging power may be, for example, a high power of 1 mW to 200 Watts (W) that may be consumed by a device load of a target device. In this description, the term “charging” may refer to supplying power to an element or a unit that charges a battery or other rechargeable device with power. Also, the term “charging” may refer supplying power to an element or a unit that consumes power. For example, the term “charging power” may refer to power consumed by a target device while operating, or power used to charge a battery of the target device. The unit or the element may include, for example, a battery, a display device, a sound output circuit, a main processor, and various types of sensors.

In this description, the term “reference resonance frequency” refers to a resonance frequency that is nominally used by the source device 110, and the term “tracking frequency” refers to a resonance frequency used by the source device 110 that has been adjusted based on a predetermined scheme.

The controller 114 may detect a reflected wave of the communication power or a reflected wave of the charging power, and may detect mismatching between the target resonator 133 and the source resonator 131 based on the detected reflected wave. The controller 114 may detect the mismatching by detecting an envelope of the reflected wave, or by detecting an amount of a power of the reflected wave.

Under the control of the controller 114, the matching network 113 compensates for impedance mismatching between the source resonator 131 and the target resonator 133 so that the source resonator 131 and the target resonator 133 are optimally-matched. The matching network 113 includes combinations of a capacitor and an inductor that are connected to the controller 114 through a switch, which is under the control of the controller 114.

The controller 114 may calculate a voltage standing wave ratio (VSWR) based on a voltage level of the reflected wave and a level of an output voltage of the source resonator 131 or the power amplifier 112. When the VSWR is greater than a predetermined value, the controller 114 detects the mismatching. In this example, the controller 114 calculates a power transmission efficiency of each of N predetermined tracking frequencies, determines a tracking frequency F_(Best) having the best power transmission efficiency among the N predetermined tracking frequencies, and changes the reference resonance frequency F_(Ref) to the tracking frequency F_(Best).

Also, the controller 114 may control a frequency of the switching pulse signal used by the power amplifier 112. By controlling the switching pulse signal used by the power amplifier 112, the controller 114 may generate a modulation signal to be transmitted to the target device 120. In other words, the communication unit 115 may transmit various messages to the target device 120 via in-band communication. Additionally, the controller 114 may detect a reflected wave, and may demodulate a signal received from the target device 120 through an envelope of the reflected wave.

The controller 114 may generate a modulation signal for in-band communication using various schemes. To generate a modulation signal, the controller 114 may turn on or off the switching pulse signal used by the power amplifier 112, or may perform delta-sigma modulation. Additionally, the controller 114 may generate a pulse-width modulation (PWM) signal having a predetermined envelope.

The communication unit 115 may perform out-of-band communication using a communication channel. The communication unit 115 may include a communication module, such as a ZigBee module, a Bluetooth module, or any other communication module, that the communication unit 115 may use to perform the out-of-band communication. The communication unit 115 may transmit or receive data 140 to or from the target device 120 via the out-of-band communication.

The source resonator 131 transfers electromagnetic energy 130, such as the communication power or the charging power, to the target resonator 133 via a magnetic coupling with the target resonator 133.

The target resonator 133 receives the electromagnetic energy 130, such as the communication power or the charging power, from the source resonator 131 via a magnetic coupling with the source resonator 131. Additionally, the target resonator 133 receives various messages from the source device 110 via the in-band communication.

The matching network 121 matches an input impedance viewed from the source device 110 to an output impedance viewed from a load. The matching network 121 may be configured with a combination of a capacitor and an inductor.

The rectifier 122 generates a DC voltage by rectifying an AC voltage received by the target resonator 133.

The DC/DC converter 123 adjusts a level of the DC voltage output from the rectifier 122 based on a voltage rating of the load. For example, the DC/DC converter 123 may adjust the level of the DC voltage output from the rectifier 122 to a level in a range from 3 volts (V) to 10 V.

The power detector 127 detects a voltage of an input terminal 126 of the DC/DC converter 123, and a current and a voltage of an output terminal of the DC/DC converter 123. The power detector 127 outputs the detected voltage of the input terminal 126, and the detected current and the detected voltage of the output terminal, to the controller 125. The controller 125 uses the detected voltage of the input terminal 126 to compute a transmission efficiency of power received from the source device 110. Additionally, the controller 125 uses the detected current and the detected voltage of the output terminal to compute an amount of power transferred to the load. The controller 114 of the source device 110 determines an amount of power that needs to be transmitted by the source device 110 based on an amount of power required by the load and the amount of power transferred to the load. When the communication unit 124 transfers an amount of power of the output terminal (e.g., the computed amount of power transferred to the load) to the source device 110, the controller 114 of the source device 110 may compute the amount of power that needs to be transmitted by the source device 110.

The communication unit 124 may perform in-band communication for transmitting or receiving data using a resonance frequency by demodulating a received signal obtained by detecting a signal between the target resonator 133 and the rectifier 122, or by detecting an output signal of the rectifier 122. In other words, the controller 125 may demodulate a message received via the in-band communication.

Additionally, the controller 125 may adjust an impedance of the target resonator 133 to modulate a signal to be transmitted to the source device 110. For example, the controller 125 may increase the impedance of the target resonator so that a reflected wave will be detected by the controller 114 of the source device 110. In this example, depending on whether the reflected wave is detected, the controller 114 of the source device 110 will detect a binary number “0” or “1”.

The communication unit 124 may transmit, to the source device 110, any one or any combination of a response message including a product type of a corresponding target device, manufacturer information of the corresponding target device, a product model name of the corresponding target device, a battery type of the corresponding target device, a charging scheme of the corresponding target device, an impedance value of a load of the corresponding target device, information about a characteristic of a target resonator of the corresponding target device, information about a frequency band used the corresponding target device, an amount of power to be used by the corresponding target device, an intrinsic identifier of the corresponding target device, product version information of the corresponding target device, and standards information of the corresponding target device.

The communication unit 124 may also perform an out-of-band communication using a communication channel. The communication unit 124 may include a communication module, such as a ZigBee module, a Bluetooth module, or any other communication module known in the art, that the communication unit 124 may use to transmit or receive data 140 to or from the source device 110 via the out-of-band communication.

The communication unit 124 may receive a wake-up request message from the source device 110, detect an amount of a power received by the target resonator, and transmit, to the source device 110, information about the amount of the power received by the target resonator. In this example, the information about the amount of the power received by the target resonator may correspond to an input voltage value and an input current value of the rectifier 122, an output voltage value and an output current value of the rectifier 122, or an output voltage value and an output current value of the DC/DC converter 123.

The controller 114 of the source device 110 may set a resonance bandwidth of the source resonator 131. Based on the set resonance bandwidth of the source resonator 131, a Q-factor Q_(S) of the source resonator 131 may be determined.

The controller 125 may set a resonance bandwidth of the target resonator 133. Based on the set resonance bandwidth of the target resonator 133, a Q-factor Q_(D) of the target resonator 133 may be determined. In this example, the resonance bandwidth of the source resonator 131 may be set to be wider or narrower than the resonance bandwidth of the target resonator 133. By communicating with each other, the source device 110 and the target device 120 may share information regarding the resonance bandwidths of the source resonator 131 and the target resonator 133. When a power higher than a reference value is requested by the target device 120, the Q-factor Q_(S) of the source resonator 131 may be set to a value greater than 100. When a power lower than the reference value is requested by the target device 120, the Q-factor Q_(S) of the source resonator 131 may be set to a value less than 100.

In resonance-based wireless power transmission, a resonance bandwidth is a significant factor. If Qt indicates a Q-factor based on a change in a distance between the source resonator 131 and the target resonator 133, a change in a resonance impedance, impedance-mismatching, a reflected signal, or any other factor affecting a Q-factor, Qt is inversely proportional to a resonance bandwidth as expressed by the following Equation 1:

$\begin{matrix} \begin{matrix} {\frac{\Delta_{f}}{f_{0}} = \frac{1}{Qt}} \\ {= {\Gamma_{S,D} + \frac{1}{{BW}_{S}} + \frac{1}{{BW}_{D}}}} \end{matrix} & (1) \end{matrix}$

In Equation 1, f₀ denotes a center frequency, Δf denotes a bandwidth, Γ_(S,D) denotes a reflection loss between resonators, BW_(S) denotes a resonance bandwidth of the source resonator 131, and BW_(D) denotes a resonance bandwidth of the target resonator 133.

An efficiency U of wireless power transmission may be expressed by the following Equation 2:

$\begin{matrix} {U = {\frac{\kappa}{\sqrt{\Gamma_{S}\Gamma_{D}}} = {\frac{\omega_{0}M}{\sqrt{R_{S}R_{D}}} = \frac{\sqrt{Q_{S}Q_{D}}}{Q_{\kappa}}}}} & (2) \end{matrix}$

In Equation 2, κ denotes a coupling coefficient of energy coupling between the source resonator 131 and the target resonator 133, Γ_(S) denotes a reflection coefficient of the source resonator 131, Γ_(D) denotes a reflection coefficient of the target resonator 133, ω₀ denotes a resonance frequency, M denotes a mutual inductance between the source resonator 131 and the target resonator 133, R_(S) denotes an impedance of the source resonator 131, R_(D) denotes an impedance of the target resonator 133, Q_(S) denotes a Q-factor of the source resonator 131, Q_(D) denotes a Q-factor of the target resonator 133, and Q_(κ) denotes a Q-factor of energy coupling between the source resonator 131 and the target resonator 133.

As can be seen from Equation 2, the Q-factor has a great effect on an efficiency of the wireless power transmission. Accordingly, the Q-factor may be set to a high value to increase the efficiency of the wireless power transmission. However, even when Q_(S) and Q_(D) are set to high values, the efficiency of the wireless power transmission may be reduced by a change in the coupling coefficient κ of the energy coupling, a change in a distance between the source resonator 131 and the target resonator 133, a change in a resonance impedance, impedance mismatching, and any other factor affecting the efficiency of the wireless power transmission.

If the resonance bandwidths BW_(S) and BW_(D) of the source resonator 131 and the target resonator 133 are set to be too narrow to increase the efficiency of the wireless power transmission, impedance mismatching and other undesirable conditions may easily occur due to insignificant external influences. In order to account for the effect of impedance mismatching, Equation 1 may be rewritten as the following Equation 3:

$\begin{matrix} {\frac{\Delta\; f}{f_{0}} = \frac{\sqrt{VSWR} - 1}{{Qt}\sqrt{VSWR}}} & (3) \end{matrix}$

The source device 110 may wirelessly transmit wake-up power used to wake up the target device 120, and may broadcast a configuration signal used to configure a wireless power transfer network. The source device 110 may receive, from the target device 120, a search frame including a value of a receiving sensitivity of the configuration signal, may permit a join of the target device 120, and may transmit an ID used to identify the target device 120 in the wireless power transfer network. Additionally, the source device 110 generates charging power through power control, and wirelessly transmits the charging power to the target device 120.

Additionally, the target device 120 may receive wake-up power from at least one of source devices, and may activate a communication function of the target device 120 using the wake-up power. The target device 120 may receive a configuration signal used to configure a wireless power transfer network of each of the source devices, may select the source device 110 based on a receiving sensitivity of the respective configuration signal, and wirelessly receives power from the selected source device 110.

FIG. 2 is a diagram illustrating an example of a wireless electromagnetic receiver 200. Referring to FIG. 2, the wireless electromagnetic receiver 200 includes an electret-based energy transducer and a solid-state resonator 210.

The energy transducer includes thin conductive layers 240 and 250, and an electret layer 260 configured close to (e.g., between) the thin conductive layers 240 and 250. The energy transducer may constitute a precharged capacitor.

The solid-state resonator 210 is configured at a side of (e.g., above), and in contact with, the energy transducer. The solid-state resonator 210 includes a shape of a plate, and is made of a magnetostrictive material of a thickness.

The wireless electromagnetic receiver 200 further includes a permanent magnet 220 configured at another side of (e.g., below) the energy transducer. A source device produces a variable magnetic field 230 through the wireless electromagnetic receiver 200 to transfer power to the wireless electromagnetic receiver 200 via the variable magnetic field 230.

The wireless electromagnetic receiver 200 further includes a load 270. The load 270 is connected to the thin conductive layers 240 and 250.

FIG. 3 is a diagram illustrating another example of a wireless electromagnetic receiver 300. Referring to FIG. 3, the wireless electromagnetic receiver 300 includes an electret-based energy transducer and a solid-state resonator 310.

The energy transducer includes thin conductive layers 340 and 350, and an electret layer 360 configured close to (e.g., between) the thin conductive layers 340 and 350. The energy transducer may constitute a precharged capacitor.

The solid-state resonator 310 is configured at a side of (e.g., a right side of), and in contact with, the energy transducer. The solid-state resonator 310 includes a shape of a cylindrical rod, and is made of a magnetostrictive material.

The wireless electromagnetic receiver 300 further includes a permanent magnet 320 configured at a side of (e.g., the right side of) the energy transducer, and at a side of (e.g., below) the solid-state resonator 310. A source device produces a variable magnetic field 330 through the wireless electromagnetic receiver 300 to transfer power to the wireless electromagnetic receiver 300 via the variable magnetic field 330.

The wireless electromagnetic receiver 300 further includes a load 370. The load 370 is connected to the thin conductive layers 340 and 350.

FIG. 4 is a diagram illustrating another example of a wireless power transfer system. Referring to FIG. 4, the wireless power transfer system includes a source device 410 and a wireless electromagnetic receiver 430.

The source device 410 is configured to generate a variable magnetic field 420, to transfer power to the wireless electromagnetic receiver 430 via the variable magnetic field 420. The wireless electromagnetic receiver 430 may include the wireless electromagnetic receiver 200 of FIG. 2 or the wireless electromagnetic receiver 300 of FIG. 3, and receives the power from the source device 410 via the variable magnetic field 420.

Referring to FIGS. 2 and 4, a first functional portion of the wireless electromagnetic receiver 430 may be represented by the solid-state resonator 210 with the permanent magnet 220. The solid-state resonator 210 may be made of a magnetostrictive material with a high Q-factor exceeding, e.g., 2000. For example, a magnetostrictive ferrite may be used as the magnetostrictive material. The solid-state resonator 210 may include, for example, a shape of a plate (as shown in FIG. 2), a cylinder (as shown in FIG. 3), a rectangular rod, a bar with a square cross-section, or other geometric shapes known to one of ordinary skill in the art. The geometric shape of the solid-state resonator 210 may be chosen so that the solid-state resonator 210 operates (e.g., oscillates) in a mechanical resonance mode at an operating frequency f. For example, for the solid-state resonator 210 to operate in a dilatational mechanical resonance mode, a size of the solid-state resonator 210, in at least one dimension, may need to be approximately equal to v/(2f) in which v is a sound velocity. The mechanical resonance mode may be an optimal method for power transfer in an example in which a maximum amount of mechanical energy is stored in the solid-state resonator 210, or power of mechanical oscillations of the solid-state resonator 210 includes a peak value.

The solid-state resonator 210 is biased by the permanent magnet 220 located at a short distance from the solid-state resonator 210 to ensure magnetostrictive properties of the magnetostrictive material forming the solid-state resonator 210, and to linearize a behavior of the solid-state resonator 210. The permanent magnet 220 may be made of a ceramic material. The permanent magnet 220 may be configured close to the solid-state resonator 210, without a considerable impact on a system efficiency.

The solid-state resonator 210 is excited by the variable magnetic field 230, or the variable magnetic field 420 of FIG. 4. That is, the variable magnetic field 230 generates the mechanical oscillations of the solid-state resonator 210 due to a magnetostrictive phenomenon. In the mechanical resonance mode, the variable magnetic field 230 is at a frequency matched to a resonance frequency f of the solid-state resonator 210.

An amplitude of the mechanical oscillations at the resonance frequency f depends on the Q-factor of the magnetostrictive material forming the solid-state resonator 210. That is, the higher the Q-factor, the higher the amplitude of the mechanical oscillations. Thus, a magnetostrictive material of a highest Q-factor may be used to form the solid-state resonator 210. Additionally, the amplitude of the mechanical oscillations depends on the magnetostrictive properties of the magnetostrictive material forming the solid-state resonator 210. Therefore, magnetostrictive materials including certain magnetostrictive properties may be used to form the solid-state resonator 210.

Referring again to FIGS. 2 and 4, a second functional portion of the wireless electromagnetic receiver 430 may be represented by the electret-based energy transducer. As discussed above in FIG. 2, the electret-based energy transducer includes the thin conductive layers 240 and 250, and the electret layer 260 configured close to (e.g., between) the thin conductive layers 240 and 250 and located near the solid-state resonator 210. The thin conductive layer 240 may be used as a metallized surface that covers a portion of a surface of the solid-state resonator 210, or as a conductor that is mechanically connected to the surface of the solid-state resonator 210. The thin conductive layer 250 is located near the solid-state resonator 210 so that the electret-based energy transducer may constitute a precharged capacitor, e.g., is not mechanically connected to the surface of the solid-state resonator 210. The electret layer 260 is configured over (e.g., above) the thin conductive layer 250. Such a combined structure of the electret-based energy transducer may ensure that the Q-factor of the solid-state resonator 210 does not decrease.

Mechanical oscillations occurring on the surface of the solid-state resonator 210 with the thin conductive layers 240 and 250 generate voltage oscillations in the energy transducer functioning as a capacitor. That is, the energy transducer transforms the mechanical oscillations into the voltage oscillations or power. The thin conductive layers 240 and 250 of the energy transducer are connected to the load 270, and the energy transducer transfers the power of the voltage oscillations to the load 270.

Referring again to FIG. 4, the wireless electromagnetic receiver 430 is used as a component of the wireless power transfer system. As discussed above, the wireless power transfer system includes the source device 410 configured to generate the variable magnetic field 420, to transfer power to the wireless electromagnetic receiver 430 via the variable magnetic field 420. The wireless power transfer system further includes the wireless electromagnetic receiver 430 configured to receive the power from the source device 410 via the variable magnetic field 420. A frequency of the variable magnetic field 420 generated by the source device 410 may correspond to a resonance frequency of the wireless electromagnetic receiver 430. Accordingly, various types of the variable magnetic field 420 may be generated based on various types of the source device 410.

In a first example, the source device 410 may include a non-radiative resonance structure with a resonance frequency f that is located at a distance less than a wavelength λ from the wireless electromagnetic receiver 430. In this example, λ=c/f, and c denotes a speed of light. Additionally, the source device 410 and the wireless electromagnetic receiver 430 constitute the wireless power transfer system.

In a second example, the source device 410 may include a non-radiative non-resonance structure. For example, the non-radiative non-resonance structure may include a coil connected to an oscillator, and may be located at a distance less than a wavelength λ from the wireless electromagnetic receiver 430. In this example, λ=c/f; and c denotes a speed of light.

In a third example, the source device 410 may include a radiative structure with a frequency f that is located at a distance greater than a wavelength λ from the wireless electromagnetic receiver 430. In this example, λ=c/f; and c denotes a speed of light.

According to the teachings above, there is provided a wireless electromagnetic receiver, namely, a component of a wireless power transfer system, which includes a solid-state resonator and an energy transducer. The solid-state resonator is excited by an external variable magnetic field to generate a mechanical energy, and the energy transducer transforms the mechanical energy into electric power. The wireless electromagnetic receiver may include a solid-state mechanical resonator with a high Q-factor configured to receive electromagnetic power with help of a magnetostrictive phenomenon.

In addition, the wireless power transfer system allows a power supply needed for low-power compact devices to be without cables or wires. The wireless power transfer system may be especially suitable for use in fields in which low frequencies are preferred, for example, in biological systems.

Additionally, according to the teachings above, there is provided a resonance-based receiver for wireless power transfer, which may include a high Q-factor and a small size, and may be applied to application products of a low frequency. For example, a value of the high Q-factor may exceed 2000, the small size may be less than or equal to 1 centimeter (cm), and the low frequency may be less than 1 MHz.

These technical effects may be attained due to the resonance-based receiver including an integral solid-state mechanical resonator made of a magnetostrictive material, and an energy transducer configured to transform a mechanical energy of the integral solid-state mechanical resonator into electric power The energy transducer is located near the integral solid-state mechanical resonator.

Furthermore, according to the teachings above, there is provided a wireless electromagnetic receiver, which includes an integral solid-state resonator that is made of a magnetostrictive material. The integral solid-state resonator may be made of a pure solid material, instead of a compound. A piezoelectric layer of the wireless electromagnetic receiver may be replaced with an energy transducer, and the energy transducer is located near the integral solid-state resonator, and may be in contact with the integral solid-state resonator. The energy transducer may be configured to avoid a decrease in a Q-factor of the integral solid-state resonator. Such a configuration and use of the energy transducer may enable a Q-factor of the wireless electromagnetic receiver to significantly increase.

For example, in an activated mode of the wireless electromagnetic receiver, the integral solid-state resonator may be driven by an external electromagnetic field at a frequency matching a resonance frequency of the integral solid-state resonator. For effective function of the wireless electromagnetic receiver, the energy transducer may be used to ensure the high Q-factor of the integral solid-state resonator. In addition, for the effective function of the wireless electromagnetic receiver, the integral solid-state resonator may be placed within a field of a permanent magnet. The wireless electromagnetic receiver may include a higher Q-factor, compared with other known technologies based on mechanical resonance.

According to the teachings above, there is provided a wireless electromagnetic receiver, which includes a mechanical resonator that is excited by a magnetic field due to a magnetostrictive phenomenon. The mechanical resonator may include a high Q-factor, for example, a Q-factor ranging from about 10³ to 10⁴, regardless of a size and a frequency of the mechanical resonator. Therefore, the mechanical resonator may be suitable for use in compact and low-frequency applications.

Additionally, according to the teachings above, there is provided a wireless power transfer system, which includes a source device and a wireless electromagnetic receiver. The source device generates a variable magnetic field to transfer power to the wireless electromagnetic receiver via the variable magnetic field, and the wireless electromagnetic receiver receives the power from the source device via the variable magnetic field.

The wireless electromagnetic receiver includes an integral solid-state mechanical resonator made of a magnetostrictive material, and an energy transducer configured to transform a mechanical energy of the integral solid-state mechanical resonator into electric power. The energy transducer is located in close vicinity to the integral solid-state mechanical resonator.

The wireless electromagnetic receiver may include an electret-based energy transducer. The electret-based energy transducer may be a capacitor precharged by an electret. Mechanical oscillations occurring on a surface of the integral solid-state mechanical resonator may generate an alternating voltage on plates of the capacitor to generate the power.

The wireless electromagnetic receiver may be used as a single component of the wireless power transfer system. A frequency of the variable magnetic field generated by the source device may be matched to a resonance frequency of the wireless electromagnetic receiver.

The units described herein may be implemented using hardware components, software components, or a combination thereof. For example, the hardware components may include microphones, amplifiers, band-pass filters, audio to digital convertors, and processing devices. A processing device may be implemented using one or more general-purpose or special purpose computers, such as, for example, a processor, a controller and an arithmetic logic unit, a digital signal processor, a microcomputer, a field programmable array, a programmable logic unit, a microprocessor or any other device capable of responding to and executing instructions in a defined manner. The processing device may run an operating system (OS) and one or more software applications that run on the OS. The processing device also may access, store, manipulate, process, and create data in response to execution of the software. For purpose of simplicity, the description of a processing device is used as singular; however, one skilled in the art will appreciated that a processing device may include multiple processing elements and multiple types of processing elements. For example, a processing device may include multiple processors or a processor and a controller. In addition, different processing configurations are possible, such as parallel processors.

The software may include a computer program, a piece of code, an instruction, or some combination thereof, to independently or collectively instruct or configure the processing device to operate as desired. Software and data may be embodied permanently or temporarily in any type of machine, component, physical or virtual equipment, computer storage medium or device, or in a propagated signal wave capable of providing instructions or data to or being interpreted by the processing device. The software also may be distributed over network coupled computer systems so that the software is stored and executed in a distributed fashion. The software and data may be stored by one or more computer readable recording mediums. The computer readable recording medium may include any data storage device that can store data which can be thereafter read by a computer system or processing device. Examples of the non-transitory computer readable recording medium include read-only memory (ROM), random-access memory (RAM), CD-ROMs, magnetic tapes, floppy disks, optical data storage devices. Also, functional programs, codes, and code segments accomplishing the examples disclosed herein can be easily construed by programmers skilled in the art to which the examples pertain based on and using the flow diagrams and block diagrams of the figures and their corresponding descriptions as provided herein.

As a non-exhaustive illustration only, a device described herein may refer to mobile devices such as a cellular phone, a personal digital assistant (PDA), a digital camera, a portable game console, and an MP3 player, a portable/personal multimedia player (PMP), a handheld e-book, a portable laptop PC, a global positioning system (GPS) navigation, a tablet, a sensor, and devices such as a desktop PC, a high definition television (HDTV), an optical disc player, a setup box, a home appliance, and the like that are capable of wireless communication or network communication consistent with that which is disclosed herein.

A number of examples have been described above. Nevertheless, it will be understood that various modifications may be made. For example, suitable results may be achieved if the described techniques are performed in a different order and/or if components in a described system, architecture, device, or circuit are combined in a different manner and/or replaced or supplemented by other components or their equivalents. Accordingly, other implementations are within the scope of the following claims. 

What is claimed is:
 1. A wireless electromagnetic receiver comprising: a first device configured to generate mechanical oscillation based on an electromagnetic field; and a second device configured to transform the mechanical oscillation of the first device into an electrical oscillation, wherein the electrical oscillation is generated in at least one of a plurality of conductive layers included in the second device, and wherein the second device includes an electret layer disposed between the plurality of conductive layers, and a quality factor (Q-factor) of the first device is maintained regardless of a change in frequency of the first device.
 2. The wireless electromagnetic receiver of claim 1, wherein: the first device comprises an integral solid-state resonator made of a magnetostrictive material, the integral solid-state resonator configured to generate the mechanical oscillation based on the electromagnetic field; and the second device configured to transform the mechanical oscillation of the integral solid-state resonator into the electrical oscillation.
 3. The wireless electromagnetic receiver of claim 1, wherein: the electromagnetic field is at a frequency corresponding to a resonance frequency of the first device.
 4. The wireless electromagnetic receiver of claim 1, wherein: the first device is made of a magnetostrictive material with a Q-factor comprising a value exceeding
 2000. 5. The wireless electromagnetic receiver of claim 1, wherein: the first device is made of a magnetostrictive ferrite.
 6. The wireless electromagnetic receiver of claim 1, wherein: the first device comprises a shape so that the power comprises a peak value at an operating frequency.
 7. The wireless electromagnetic receiver of claim 1, wherein: the first device comprises a shape of a cylinder.
 8. The wireless electromagnetic receiver of claim 1, wherein: the first device comprises a shape of a bar with a square cross-section.
 9. The wireless electromagnetic receiver of claim 1, wherein: the first device comprises a shape of a plane.
 10. The wireless electromagnetic receiver of claim 1, further comprising: a permanent magnet configured to bias the first device.
 11. The wireless electromagnetic receiver of claim 10, wherein: the permanent magnet is made of magnetic ceramics.
 12. The wireless electromagnetic receiver of claim 1, wherein: the second device comprises a precharged capacitor.
 13. The wireless electromagnetic receiver of claim 1, wherein at least one of the plurality of conductive layers comprises: a metallized surface configured to cover a portion of a surface of the first device.
 14. The wireless electromagnetic receiver of claim 1, wherein at least one of the plurality of conductive layers comprises: a conductor mechanically connected to a surface of the first device.
 15. The wireless electromagnetic receiver of claim 1, wherein: at least one of the plurality of conductive layers is not mechanically connected to the first device.
 16. A wireless power transfer system comprising: a transmitter configured to generate a magnetic field to transmit power; and a wireless electromagnetic receiver configured to receive the power from the transmitter, wherein the wireless electromagnetic receiver comprises a first device configured to generate mechanical oscillation based on the magnetic field; and a second device configured to transform the mechanical oscillation of the first device into an electrical oscillation, wherein the electrical oscillation is generated in a plurality of conductive layers included in the second device and wherein the second device includes an electret layer disposed between the plurality of conductive layers, and a quality factor (Q-factor) of the first device is maintained regardless of a change in frequency of the first device.
 17. The wireless power transfer system of claim 16, wherein: the first device comprises an integral solid-state resonator made of a magnetostrictive material, the integral solid-state resonator configured to generate the mechanical oscillation based on the magnetic field; and the second device comprises a transducer configured to transform the oscillation of the integral solid-state resonator into the electrical oscillation.
 18. The wireless power transfer system of claim 16, wherein: the magnetic field is at a frequency corresponding to a resonance frequency of the first device.
 19. The wireless power transfer system of claim 16, wherein: the first device is made of a magnetostrictive material with a Q-factor comprising a value exceeding
 2000. 20. The wireless power transfer system of claim 16, wherein: the first device is made of a magnetostrictive ferrite.
 21. The wireless power transfer system of claim 16, wherein: the first device comprises a shape so that the power comprises a peak value at an operating frequency.
 22. The wireless power transfer system of claim 16, wherein: the first device comprises a shape of a cylinder.
 23. The wireless power transfer system of claim 16, wherein: the first device comprises a shape of a bar with a square cross-section.
 24. The wireless power transfer system of claim 16, wherein: the first device comprises a shape of a plane.
 25. The wireless power transfer system of claim 16, further comprising: a permanent magnet configured to bias the first device.
 26. The wireless power transfer system of claim 25, wherein: the permanent magnet is made of magnetic ceramics.
 27. The wireless power transfer system of claim 16, wherein: the second device comprises a precharged capacitor.
 28. The wireless power transfer system of claim 16, wherein at least one of the plurality of conductive layers comprises: a metallized surface configured to cover a portion of a surface of the first device.
 29. The wireless power transfer system of claim 16, wherein at least one of the plurality of conductive layers comprises: a conductor mechanically connected to a surface of the first device.
 30. The wireless power transfer system of claim 16, wherein: at least one of the plurality of conductive layers is not mechanically connected to the first device.
 31. The wireless power transfer system of claim 16, wherein the transmitter comprises: a non-radiative resonance structure with a resonance frequency f that is located at a distance less than a wavelength λ from the wireless electromagnetic receiver, wherein λ=c/f, and c denotes a speed of light.
 32. The wireless power transfer system of claim 16, wherein the transmitter comprises: a non-radiative non-resonance structure located at a distance less than a wavelength λ from the wireless electromagnetic receiver, wherein λ=c/f, and c denotes a speed of light.
 33. The wireless power transfer system of claim 16, wherein the transmitter comprises: a radiative structure with a frequency f that is located at a distance greater than a wavelength λ from the wireless electromagnetic receiver, wherein λ=c/f, and c denotes a speed of light. 